KR20010110121A - Plasma display panel and plasma display device - Google Patents

Abstract

A plasma display panel in which the white color temperature can be set to an appropriate value is performed without adjusting the input gain which causes a decrease in the number of gradations.

In the scan electrode 2, the width of the transparent electrode 2b is varied for each color such that the relationship between the widths WR0, WG1, and WB1 in the Y direction of the transparent electrodes 2bR, 2bG, and 2bB is WB1> WR0> WG1. . Similarly, in the sustain electrode 3, the width of the transparent electrode 3b is varied for each color such that the relationship between the widths WR0, WG1, and WB1 in the Y direction of the transparent electrodes 3bR, 3bG, and 3bB is WB1> WR0> WG1. Do it differently.

Description

Plasma Display Panel and Plasma Display Device {PLASMA DISPLAY PANEL AND PLASMA DISPLAY DEVICE}

The present invention relates to a structure of an AC surface discharge type color plasma display panel of a matrix display system and a plasma display device including the plasma display panel (hereinafter referred to as "PDP").

14 is a perspective view showing a cell structure of a conventional AC surface discharge type PDP. FIG. 15 is a schematic diagram showing the arrangement relationship between the scan electrode 102, the sustain electrode 103, and the partition wall 108 when viewed from the X-direction shown in FIG. 14. In general, the AC surface discharge type PDP of the matrix display system is composed of a front panel on the display surface side and a rear panel facing the front panel via a discharge space. On the main surface (surface on the side opposite the rear panel) of the glass substrate 101 of the front panel, the scan electrode 102 and the sustain electrode 103 are parallel and symmetrically in each discharge cell via the discharge gap which is the center of the discharge. A plurality of pairs (only one pair is shown in Figs. 14 and 15) are arranged at intervals of the pixel pitch along the Z direction in the figure.

Referring to FIG. 15, the scan electrode 102 is connected to the mother electrode 102a extending in the Y direction and the mother electrode 102a in the figure, and the transparent electrode 102b protruding in the Z direction in the figure (in FIG. 15). In the reference numerals 102bR1, 102bG, 102bB, and 102bR2. In addition, the sustain electrode 103 is connected to the mother electrode 103a extending in the Y direction and the mother electrode 103a and protruding in the Z direction to define a discharge gap between the transparent electrode 102b and the transparent electrode 103b. (The symbols 103bR1, 103bG, 103bB, and 103bR2 in FIG. 15). The lengths L102b0 and L103b0 in the Z direction and the widths WR0, WG0 and WB0 in the Y direction of the transparent electrodes 102 and 103 are equal to each other between the respective discharge cells. Moreover, the space | interval G0 of the Z direction of a discharge gap is equal to each other between each discharge cell.

The transparent electrodes 102b and 103b are made of a material having a relatively high transmittance of visible light such as ITO (Indium Tin 0xide) or SnO 2 (NESA), and are often formed by a thin film process such as vapor deposition or CVD. In addition, the mother electrodes 102a and 103a are made of a relatively low resistance material such as silver, aluminum, copper or chromium, and a copper multilayer film, and use a thick film process or a photosensitive paste using a printing process. It is formed by a thin film process.

Moreover, the dielectric layer 104 is formed on the main surface of the glass substrate 101 covering the scanning electrode 102 and the sustain electrode 103. The surface of the dielectric layer 104 (surface exposed to the discharge space) is covered by a protective film 105 such as MgO having a relatively high secondary electron emission coefficient and excellent sputter resistance to ions and electrons generated by discharge. have.

On the main surface (surface on the side opposite to the front panel) of the glass substrate 106 of the rear panel, a plurality of partition walls 108 having a predetermined height are arranged in the Y direction in order to define / specify a discharge space between the front panel and the rear panel. It is formed extending in the Z direction between discharge cells adjacent to each other. On the main surface of the glass substrate 106, a plurality of writing electrodes 107 (reference numerals 107R, 107G, and 107B in FIG. 14) extending in the Z direction are formed between the partition walls 108 adjacent to each other. It is.

The surface of the concave portion formed by the side surface of the partition 108 and the main surface of the glass substrate 106 is covered with the writing electrode 107 to correspond to each color of red (R), green (G) and blue (B). Predetermined phosphor 109 (symbols 109R, 109G, 109B in Fig. 14) is applied. In addition, an insulating layer may be provided between the writing electrode 107 and the phosphor 109.

The front panel and the back panel are sealed to each other by a sealing material (not shown) disposed at the periphery of the panel by contacting the top of the partition 108 and the protective film 105. In each discharge space of the PDP formed by the front panel, the back panel, and the sealing material and partitioned by the partition 108, a rare gas such as Xenon, a rare gas such as Xenon, and a discharge gas such as nitrogen or oxygen can be discharged. Gas is enclosed. The phosphor 109 is excited by the ultraviolet rays generated by the discharge and emits light in each color.

Fig. 16 is a schematic diagram for simplifying the process until the discharge cells emit light in the conventional PDP. A predetermined voltage is applied between the scan electrode 102 and the write electrode 107 with respect to the discharge cell to be turned on to cause discharge between both electrodes. This is called address discharge, and cations and electrons that are ionized by the address discharge accumulate on the surfaces of the phosphor 109 and the protective film 105 as wall charges.

In the discharge cells in which the wall charges have accumulated, when a voltage is applied to the sustain electrode 103, creepage discharge is started through the discharge gap between the scan electrode 102 and the sustain electrode 103. Thereafter, an alternating electric field is applied to the scan electrode 102 and the sustain electrode 103, whereby the discharge is repeatedly performed by the scan electrode 102 and the sustain electrode 103. As described above, the discharge repeatedly performed between the scan electrode 102 and the sustain electrode 103 by the application of an alternating electric field is called sustain discharge, and the ultraviolet rays generated by the sustain discharge excite the phosphor 109 to produce visible light. It penetrates the front panel and radiates to the outside.

When gradation display is performed in a PDP, it is common to employ a time division gradation method in which gradation is expressed by controlling the luminance by controlling the number of sustain discharges in one field period of an image. One field period is divided into several small time units called subfields SF, and a pulse voltage for performing sustain discharge is inserted in each subfield by the weighted number based on the binary method. For example, if one field is divided into eight subfields (SF0 to SF7), and a sustain pulse is inserted into each subfield at a ratio of 1: 2: 4: 8: 16: 32: 64: 128, By combining the subfields, luminance of 256 gray levels can be expressed. By performing such control with respect to the discharge cells of each color, approximately 16.7 million colors can be expressed.

When white is displayed using a PDP using such a time division gray scale display method, 256 grays can be displayed by mixing gains of red, green, and blue input signals in a ratio of 1: 1. . In particular, when all colors are displayed with maximum gain, in theory, white display at maximum luminance is possible. In this case, white is a standard at a color temperature of 6500K in the blackbody radiation trajectory drawn on the CIExy chromaticity diagram.

However, when white is displayed on the actual PDP, even when the phosphors 109R, 109G, and 109B are irradiated with the same amount of ultraviolet light in a mixing ratio of 1: 1, there is a case where white is not displayed or the color temperature is lowered. This is due to the poor balance of the visible light of each color obtained and the influence of the visible light of the discharge gas itself other than the visible light from the phosphor 109. In particular, the cause of lowering the color temperature is largely due to the light emission characteristics of the blue phosphor 109B. For this reason, when white is displayed on the PDP, gain adjustment of the input signal is performed such that the gains of red and green are reduced compared to blue. For example, it adjusts as R: G: B = 0.8: 0.5: 1 and displays the white color of desired color temperature.

However, by performing the above-described adjustment of the input gain, 256 gray scale display cannot be performed for red or green. For example, in a PDP capable of displaying 256 gray levels (16.7 million colors) in each color, as described above, when the input gain of each color is adjusted to R: G: B = 0.8: 0.5: 1, the blue 256 gray scales are displayed. On the other hand, there is a problem that red is 256 gray x 0.8 = 204 gray, green is 256 gray x 0.5 = 128 gray, and the number of grays decreases, respectively, and the gray scale display quality is remarkably impaired.

Japanese Patent Application Laid-Open No. 10-308179 discloses that the light emitting area of the phosphor is changed for each color by changing the width of the phosphor for each color, whereby the white color temperature is appropriately adjusted without adjusting the input gain. The invention which aims at setting to is disclosed. However, in the invention described in the above publication, by varying the width of the phosphor, the voltage margin of the discharge cell can be varied for each color, so that erroneous discharge can occur.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems in a conventional PDP, and to adjust the white color temperature without adjusting the input gain that causes the decrease in the number of gradations and without the occurrence of false discharge. The present invention provides a plasma display panel that can be set to a value and a plasma display device including the plasma display panel.

1 is a perspective view showing a cell structure of a PDP;

2 is a schematic diagram showing the structure of a PDP according to Embodiment 1 of the present invention;

3 is a schematic diagram showing the structure of a PDP according to a second embodiment of the present invention;

4 is a schematic diagram showing the structure of a PDP according to a combination of Example 1 and Example 2 of the present invention;

5 is a schematic diagram showing the structure of a PDP according to a third embodiment of the present invention;

6 is a schematic diagram showing the structure of a PDP according to the combination of Examples 1 to 3 of the present invention;

7 is a schematic diagram showing the structure of a PDP according to Modification Example 1 of the present invention;

8 is a schematic diagram showing the structure of a PDP according to Modification Example 2 of the present invention;

9 is a schematic diagram showing the structure of a PDP according to Modification Example 3 of the present invention;

10 is a schematic diagram showing the structure of a PDP according to Modification Example 4 of the present invention;

11 is a schematic diagram showing another structure of the PDP according to Modification Example 4 of the present invention;

12 is a schematic diagram showing the structure of a PDP according to Modification Example 5 of the present invention;

13 is a schematic diagram showing the structure of a PDP according to Modification Example 6 of the present invention;

14 is a perspective view showing a cell structure of a conventional PDP;

15 is a schematic diagram showing the arrangement relationship between the scan electrode, the sustain electrode, and the partition wall with respect to the conventional PDP;

16 is a schematic diagram for explaining an operation of a conventional PDP.

Explanation of symbols for the main parts of the drawings

1, 6: glass substrate 2: scanning electrode

3: sustain electrode 4: dielectric layer

5: protective film 7R, 7G, 7B: write electrode

8: partition 9, 9R, 9G, 9B: phosphor

According to a first aspect of the present invention, a plasma display panel includes: a first substrate serving as a display surface; a second substrate facing the first substrate with a discharge space in which a plurality of unit discharge regions are arranged in a matrix; It is formed on the main surface of the 1st board | substrate of a space side, is formed on the main surface of the pair of 1st electrode and 2nd electrode provided for each row of a some unit discharge area | region, and the main surface of the 2nd board | substrate of a discharge space side, And a third electrode provided for each column of the unit discharge region of the substrate, and at least two or more kinds of phosphors formed on the main surface of the second substrate to cover the third electrode and having different emission colors, wherein the first electrode is in a row direction; A trunk portion extending along the direction and a branch portion connected to the trunk portion and provided for each unit discharge region and protruding in a second direction in the column direction,The second electrode has a trunk portion extending along the first direction and a branch portion connected to the trunk portion, provided for each unit discharge region, and having a branch portion protruding in the second direction to define a discharge gap between the branch portions of the first electrode. The area of at least one of the branch portions of the first electrode and the second electrode is different from each other among the plurality of unit discharge regions for each color of emission.

In addition, the plasma display panel according to the second aspect of the present invention is the plasma display panel according to the first aspect, wherein a width in a first direction of at least one of the branch portions of the first electrode and the second electrode has a plurality of unit discharge regions per emission color. It is characterized by different things.

In addition, the plasma display panel according to the third aspect of the present invention is a plasma display panel according to the first or second aspect, wherein the length of the second direction of at least one branch of the first electrode and the second electrode is plural for each of the emission colors. It is characterized in that they are different from each other in the unit discharge region.

In addition, the plasma display panel according to the fourth aspect of the present invention is the plasma display panel according to the third aspect, wherein the lengths of the branch portions of the first electrode in the second direction are different between the plurality of unit discharge regions, The trunk portion is characterized in that the trunk portion is disposed on an end portion on the side opposite to the discharge gap of the branch portion having the shortest length in the second direction.

Further, the plasma display panel according to the fifth aspect of the present invention is the plasma display panel according to any one of the first to fourth aspects, wherein the intervals in the second direction of the discharge gap are different between the plurality of unit discharge regions for each of the emission colors. It is characterized by.

In addition, the plasma display panel according to the sixth aspect of the present invention is the plasma display panel according to any one of the first to fifth aspects, wherein a branch area of only one of the first electrode and the second electrode has a plurality of unit regions. It is characterized by different things.

The plasma display panel according to the seventh aspect of the present invention is the plasma display panel according to any one of the first to sixth aspects, wherein the trunk portion of the first electrode and the branch portion of the first electrode are integrally formed of the same material. It is characterized by being formed.

The plasma display panel according to the eighth aspect of the present invention is the plasma display panel according to any one of the first to seventh aspects, wherein the branch portion of the first electrode is a frame-shaped metal electrode having the same shape as the outer peripheral line of the branch portion. It is characterized by.

The plasma display panel according to the ninth aspect of the present invention is the plasma display panel according to the eighth aspect, wherein the trunk portion of the first electrode is a metal electrode, and the trunk portion of the first electrode and the branch portion of the first electrode are integrally formed. It is characterized by being formed.

The plasma display panel according to the tenth aspect of the present invention is the plasma display panel according to the ninth aspect, wherein the trunk portion of the first electrode is formed only outside the outer circumferential line of the branch portion of the first electrode.

In addition, the plasma display panel according to the eleventh aspect of the present invention includes a first substrate serving as a display surface, a second substrate facing the first substrate with a discharge space including a plurality of unit discharge regions arranged in a matrix shape; Is formed on the main surface of the first substrate on the discharge space side, and is formed on the main surface of the paired first and second electrodes provided on each row of the plurality of unit discharge regions, and on the main surface of the second substrate on the discharge space side. And a third electrode provided for each column of the plurality of unit discharge regions, and at least two or more kinds of phosphors formed on the main surface of the second substrate by covering the third electrode and having different emission colors, wherein the first electrode is in a row direction. A trunk portion extending along the first direction, and a branch portion connected to the trunk portion for each unit discharge region and protruding in the second direction in the column direction, and the second electrode is along the first direction. The device has a trunk portion and a branch portion connected to the trunk portion and provided in each unit discharge region and protruding in a second direction to define a discharge gap between the branch portions of the first electrode, and the branch portion in the second direction of the discharge gap. The interval is characterized in that the light emission color is different between the plurality of unit discharge regions.

The plasma display panel according to the twelfth aspect of the present invention is a plasma display panel according to any one of the first to eleventh aspects, and includes a dielectric layer formed on the main surface of the first substrate by covering the first electrode and the second electrode. Further, the phosphor is formed on the surface of the dielectric layer in a portion which does not overlap with the branch portion of the first electrode and the branch portion of the second electrode in planar view.

In addition, the plasma display device according to the thirteenth aspect of the present invention includes the plasma display panel according to any one of the first to twelfth features and a driving circuit for driving the plasma display panel.

(Example of the invention)

1 is a perspective view illustrating a cell structure of a PDP. Although only one pixel cell structure is shown in Fig. 1, in the actual PDP, a plurality of discharge cells in accordance with the number of pixels are arranged in a matrix to form a discharge cell matrix. As shown in Fig. 1, the PDP according to the present invention has a front panel and a rear panel facing each other with a discharge space therebetween. The front panel is formed on the glass substrate 1, which is the display surface, and on the main surface of the glass substrate 1 (surface on the side opposite to the glass substrate 6). The dielectric layer 4 formed on the main surface of the glass substrate 1 is formed by covering the scan electrode 2 and the sustain electrode 3, the scan electrode 2, and the sustain electrode 3. On the surface (surface exposed to the discharge space) of the dielectric layer 4, a protective film 5 made of Mg0 or the like is formed.

In addition, the back panel extends in the Z direction in the drawing on the glass substrate 6 and the main surface of the glass substrate 6 (the surface on the side opposite to the glass substrate 1) (Fig. Reference numerals 7R, 7G, and 7B in 1, the partition wall 8 formed in the Z direction, and the writing electrode (between the writing electrodes 7 adjacent to each other on the main surface of the glass substrate 6) 7) a predetermined phosphor 9 corresponding to each color of red, green, and blue applied to the surface of the concave portion formed by covering the side surface of the partition 8 and the main surface of the glass substrate 6 (in FIG. 1). Symbol (9R), 9G, 9B).

The present invention relates to the structure of the front panel, in particular the structure of the scan electrode 2 and the sustain electrode 3. Hereinafter, the Example of this invention is described concretely.

(Example 1)

FIG. 2 shows the scan electrodes 2, the sustain electrodes 3, and the partitions 8 in the case where four adjacent discharge cells in the PDP according to the first embodiment of the present invention are viewed along the X direction from the front panel side. It is a schematic diagram shown. The scanning electrode 2 is connected to the mother electrode 2a extending in the Y direction and the mother electrode 2a, and the transparent electrode 2b projecting in the Z direction toward the center side of the discharge cell (symbol in FIG. 2). (2bR1, 2bG, 2bB, and 2bR2). The transparent electrodes 2bR1, 2bG, 2bB, and 2bR2 are each formed individually for each discharge cell, and overlap each other at the end opposite to the discharge gap. It is electrically connected with each other only by the mother electrode 2a.

In addition, the sustain electrode 3 is connected to the mother electrode 3a and the mother electrode 3a extending in the Y direction and protrudes in the Z direction toward the center side of the discharge cell to discharge gaps in the gap with the transparent electrode 2b. It is comprised by the transparent electrode 3b (symbol 3bR1, 3bG, 3bB, 3bR2 in FIG. 2) which prescribe | regulates. The transparent electrodes 3bR1, 3bG, 3bB, and 3bR2 are each formed individually for each discharge cell, and are electrically connected to each other only by the mother electrode 3a which overlaps at the end opposite to the discharge gap. In addition, in Example 1, all the space | intervals of the Z direction of the discharge gap between the transparent electrode 2b and the transparent electrode 3b are equal to G0.

The scan electrode 2 and the sustain electrode 3 form the transparent electrodes 2b and 3b on the main surface of the glass substrate 1, and then partially overlap the glass electrodes 1 on the transparent electrodes 2b and 3b. It is obtained by forming the mother electrodes 2a and 3a on the main surface of the parenthesis.

In the PDP according to the present invention, the area of the transparent electrodes 2b and 3b is varied for each color according to the light emission characteristics of the phosphors 9R, 9G and 9B, thereby irradiating the ultraviolet light to the phosphors 9R, 9G and 9B. The luminous intensity is adjusted for each color by making different for each color. Therefore, in Example 1, the width | variety of the Y direction of the transparent electrodes 2b and 3b changes for each color of R, G, and B. FIG. Hereinafter, the case where the relationship of luminescence intensity when the same amount of ultraviolet rays are irradiated is G> R> B is demonstrated as an example. However, the relationship between the luminescence intensities depends on the luminescence properties of the phosphor to be used.

As shown in Fig. 15, in the conventional PDP, since the areas of the transparent electrodes 102b and 103b were equal between the colors, the relationship between the luminescence intensities when the same amount of ultraviolet rays was irradiated is also G> R> B. That is, since the luminous intensity of green is strong and the luminous intensity of blue is weak, the color temperature in the case of displaying white becomes low. As a result, the gain of the input signal must be adjusted to reduce the number of gradations.

In contrast, in the first embodiment, the relationship between the widths WR0, WG1, and WB1 in the Y direction of the transparent electrodes 2bR (symbols 2bR1 and 2bR2 in FIG. 2) and (2bG and 2bB) is WB1> WR0> WG1. The width of the transparent electrode 2b is varied for each color so as to be. Here, the lengths in the Z direction of the transparent electrode 2b are all equal to L2b0.

Similarly, the transparent electrodes 3bR (symbols 3bR1 and 3bR2 in FIG. 2) and the widths WR0, WG1, and WB1 in the Y-direction of the 3bG and 3bB are set to WB1> WR0> WG1. The width of 3b) is different for each color. Here, the lengths in the Z direction of the transparent electrode 3b are all equal to L3b0.

Thereby, according to the magnitude | size of the area of the transparent electrodes 2b and 3b, the ultraviolet irradiation amount in each discharge cell becomes B> R> G, and it is blue compared with red and green discharge cells in the example shown in FIG. The amount of ultraviolet irradiation in the discharge cell can be increased.

As described above, according to the PDP according to the first embodiment, the discharge cells having a smaller emission intensity in the case where the same amount of ultraviolet rays are irradiated according to the light emission characteristics of the phosphors 9R, 9G, and 9B are transparent electrodes 2b and 3b. Increase the width of). As a result, the amount of ultraviolet irradiation to the phosphors 9R, 9G, and 9B can be different for each color, and therefore, unlike the conventional PDP that adjusts the input gain, the white color is not reduced without reducing the number of gray levels of each color. The temperature can be set to an appropriate value.

(Example 2)

In Example 1, the widths of the transparent electrodes 2b and 3b were varied between discharge cells in accordance with the light emission characteristics of the phosphors 9R, 9G and 9B. However, as shown in FIG. 2, in the discharge cells having the widest transparent electrodes 2bB and 3bB, the distance in plan view between the transparent electrodes 2bB and 3bB and the partition wall 8 becomes short, and the front panel is shortened. Due to misalignment at the time of joining the back panel together, a part of the transparent electrodes 2b, 3b may overlap with the planar sagittal partition 8. When a part of transparent electrode 2b, 3b overlaps with partition 8, since sustain discharge does not generate | occur | produce in the overlapped part, the effective area of transparent electrode 2b, 3b becomes small substantially, The said embodiment The effect planned at 1 is reduced. Moreover, in the transparent electrodes 2b and 3b of the part which overlapped with the partition 8, the consumption of the invalid electric power which does not contribute to discharge generate | occur | produces.

For this reason, the widths of the transparent electrodes 2b and 3b are limited by the amount of misalignment expected when joining the front panel and the back panel. For example, the transparent electrodes 2b and 3b and the partition wall when the distance between the adjacent partition walls 8 (that is, the width in the Y direction of the discharge space) are 350 µm and the expected amount of misalignment is 50 µm. In order that (8) does not overlap with each other in plan view, the maximum value of the width of the transparent electrodes 2b and 3b is equal to 250 µm in anticipation of a margin of 50 µm each in the left and right directions.

Therefore, in the second embodiment, a description will be given of a PDP which can achieve the same effect as in the first embodiment while ensuring sufficient margin for the misalignment.

Fig. 3 extracts scan electrodes 2, sustain electrodes 3, and partitions 8 in the case where four adjacent discharge cells in the PDP according to the second embodiment of the present invention are viewed along the X direction from the front panel side. It is a schematic diagram shown. As shown in Fig. 3, in the second embodiment, the lengths of the transparent electrodes 2b and 3b in the Z direction are different for each color of R, G and B. Hereinafter, the case where the relationship of luminescence intensity when the same amount of ultraviolet rays are irradiated is G> R> B is demonstrated as an example. However, as described above, the relationship between the light emission intensities depends on the light emission characteristics of the phosphor to be used.

Referring to FIG. 3, in the second embodiment, the relationship between the lengths L2b1, L2b0, and L2b2 in the Z direction of the transparent electrodes 2bR (symbols 2bR1 and 2bR2 in FIG. 3) and (2bG and 2bB) is L2b2>. The length of the transparent electrode 2b is varied for each color so that L2b1> L2b0. Here, the widths WR0, WG0, and WB0 in the Y-direction of the transparent electrodes 2bR, 2bG, and 2bB are all equivalent.

Similarly, the transparent electrodes 3bR (symbols 3bR1 and 3bR2 in FIG. 3) and the lengths L3b1, L3b0, and L3b2 in the Z-direction of (3bG, 3bB) become L3b2> L3b1> L3b0. The length of 3b) is different for each color. Here, the widths WR0, WG0, and WB0 in the Y-direction of the transparent electrodes 3bR, 3bG, and 3bB are all equivalent.

Thereby, in the discharge cell which lengthened the transparent electrode 2b, 3b, the discharge space expands to a Z direction. That is, the area of the phosphors 9R, 9G, and 9B to which ultraviolet rays generated by sustain discharge are irradiated according to the magnitude of the area of the transparent electrodes 2b and 3b due to the difference in the length in the Z direction is B> R> G. Therefore, in the example shown in FIG. 3, the ultraviolet irradiation amount in the blue discharge cell can be increased as compared with the red and green discharge cells.

In addition, similarly to the first embodiment, in the second embodiment, the intervals in the Z-direction of the discharge gap between the transparent electrode 2b and the transparent electrode 3b are all equal to G0. At this time, in order to prevent erroneous discharge due to interference with discharge cells (not shown in Fig. 3) adjacent to each other in the Z direction, the interval G0 of the discharge gap needs to be defined as follows. That is, paying attention to the longest transparent electrode (transparent electrodes 2bB and 3bB in Fig. 3), the transparent electrode present on the top of the transparent electrode 2bB shown in Fig. 3 and on the surface of the transparent electrode 2bB is actually present. The interval between the lower end of 3bB and the lower end of the transparent electrode 3bB shown in FIG. 3 and the upper end of the transparent electrode 2bB actually present below the transparent electrode 3bB on the ground are the gaps between the discharge gaps. It is necessary to define the interval G0 of the discharge gap so as to be larger than G0.

As described above, according to the PDP according to the second embodiment, according to the light emission characteristics of the phosphors 9R, 9G, and 9B, the discharge cells having a smaller emission intensity in the case where the same amount of ultraviolet rays are irradiated are provided with the transparent electrodes 2b, Lengthen the length of 3b). As a result, as in the first embodiment, since the amount of ultraviolet irradiation to the phosphors 9R, 9G, and 9B can be different for each color, the color temperature of white can be set to an appropriate value without reducing the number of gray levels of each color. Will be.

Unlike the first embodiment, since the widths of the transparent electrodes 2b and 3b are not expanded, the tolerances of misalignment when joining the front panel and the back panel can be sufficiently secured for each color. have.

As shown in FIG. 3, the parent electrodes 2a and 3a are different from the discharge gaps of the shortest transparent electrodes 2b and 3b (the transparent electrodes 2bG and 3bG in the example shown in FIG. 3). It is preferable to arrange on the opposite end. Thereby, the fall of the luminescence brightness resulting from presence of the mother electrode 2a, 3a can be suppressed most effectively.

The invention according to the second embodiment may be applied in combination with the invention according to the first embodiment. FIG. 4 is a schematic diagram showing the scan electrodes 2, the sustain electrodes 3, and the partitions 8 when four adjacent discharge cells in the PDP according to this combination are seen along the X direction from the front panel side. . In the PDP shown in FIG. 4, the transparent electrodes 2b and 3b are changed in the same manner as in Example 1 in order to change the areas of the transparent electrodes 2b and 3b according to the light emission characteristics of the phosphors 9R, 9G and 9B. In the Y direction, the width in the Y direction is changed for each color, and the length in the Z direction of the transparent electrodes 2b and 3b is changed for each color as in the second embodiment. In addition, all the space | intervals in the Z direction of the discharge gap between the transparent electrode 2b and the transparent electrode 3b are equal to G0.

As described above, by applying the invention according to the second embodiment in combination with the invention according to the first embodiment, the phosphors 9R and 9G have a small emission intensity when the same amount of ultraviolet light is irradiated. , 9B) can increase the effect of increasing the amount of ultraviolet radiation.

(Example 3)

In the discharge cells in which the wall charges are accumulated by the write discharge, the sum (holding voltage) of the voltage caused by the wall charges and the external voltage applied to the scan electrode 2 exceeds the start voltage of the sustain discharges in the sustain discharge period. When this occurs, sustain discharge occurs between the sustain electrodes 3. At this time, due to the light emission characteristics of the phosphors 9R, 9G, and 9B, the start voltage of the address discharge is different for each discharge cell of each color. And since the amount of wall charges which accumulate is small in the discharge cell with the high start voltage of write discharge, erroneous discharge may generate that the discharge cell which should be lit does not light up. This misdischarge can be prevented by applying a certain voltage margin to the sustain voltage relative to the start voltage of the sustain discharge, and applying a high external voltage.

However, when such control is executed, an excessive external voltage is applied to the discharge cells in which the start voltage of the write discharge is low and the wall charge is sufficiently accumulated, and the reset discharge is executed until the write discharge of the next subfield. This does not run enough. As a result, other false discharge may occur, in which the write discharge occurs in the discharge cell which is not scheduled to perform the write discharge. Moreover, since most of the power consumption of the PDP is caused by sustain discharge, when the sustain voltage is high, the power consumption increases. Moreover, although the method of setting the voltage which performs write discharge individually for each fluorescent substance of each color can also be considered, since three types of external power supply need to be prepared, it raises cost.

In view of the above-described problems, the third embodiment describes a PDP capable of equalizing the occurrence probability of sustain discharge in discharge cells of each color using only one type of external power source.

FIG. 5 is a diagram illustrating extracting the scan electrode 2, the sustain electrode 3, and the partition wall 8 when the four adjacent discharge cells in the PDP according to the third embodiment of the present invention are viewed along the X direction from the front panel side. It is a schematic diagram shown. As shown in Fig. 5, in the third embodiment, the interval in the Z direction of the discharge gap between the transparent electrode 2b and the transparent electrode 3b is different for each color of R, G, and B. Hereinafter, the case where the relationship of the start voltage of write discharge is G> R> B is demonstrated as an example. However, the relationship between this discharge start voltage differs depending on the light emission characteristics of the phosphor to be used.

Referring to FIG. 5, in the third embodiment, between the transparent electrode 2bR (symbols 2bR1 and 2bR2 in FIG. 5) and the transparent electrode 3bR (symbols 3bR1 and 3bR2 in FIG. 5). The relationship between the discharge gap G0, the discharge gap G1 between the transparent electrode 2bG and the transparent electrode 3bG, and the discharge gap G2 between the transparent electrode 2bB and the transparent electrode 3bB is set to be G1> G0> G2. Here, the widths of the transparent electrodes 2b and 3b are equal.

Since the voltages applied between the scan electrodes 2 and the write electrodes 7R, 7G, and 7B at the time of writing are equal among all discharge cells of each color, it is due to the difference in the light emission characteristics of the phosphors 9R, 9G, and 9B. Thus, the accumulation amount of the wall charges due to the address discharge is in the relation of R> B> G.

In the third embodiment, in accordance with the difference in the start voltage of the write discharge due to the difference in the light emission characteristics of the phosphors 9R, 9G, and 9B, in other words, the ease of generating sustain discharge due to the difference in the amount of charge accumulated after writing. Accordingly, the gap between the discharge gaps is made different for each discharge cell of each color. Specifically, the interval between the discharge gaps is set so that the discharge cells with a higher start voltage for write discharges become smaller.

Therefore, according to the PDP according to the third embodiment, when voltage is applied to the scan electrode 2 from the external power supply in the subsequent discharge sustain period, the start of sustain discharge irrespective of the amount of wall charges stored is large or small. Since the voltage margin of the sustain voltage with respect to the voltage can be made uniform among the discharge cells of each color, it becomes possible to suppress the variation in the occurrence probability of the sustain discharge between the discharge cells of each color. As a result, it is possible to prevent the occurrence of the above false discharge due to insufficient reset discharge being performed.

The invention according to the third embodiment can also be applied in combination with the inventions according to the first and second embodiments. Fig. 6 extracts the scan electrode 2, sustain electrode 3, and partition 8 when the four adjacent discharge cells in the PDP according to the combination of Examples 1 to 3 are viewed along the X direction from the front panel side. It is a schematic diagram shown. In the PDP shown in Fig. 6, the width in the Y direction of the transparent electrodes 2b and 3b is changed for each color as in the first embodiment, and the transparent electrodes 2b and 3b are similar to the second embodiment. The length in the Z direction is different for each color, and as in the present embodiment, the interval in the Z direction of the discharge gap is different for each color.

As described above, by applying the invention according to the third embodiment in combination with the inventions according to the first and second embodiments, the phosphor 9R is regarded as a discharge cell having a small luminescence intensity when the same amount of ultraviolet light is irradiated. And 9G, 9B), the effect of increasing the amount of ultraviolet irradiation can be obtained, and the effect of suppressing the variation in the probability of occurrence of sustain discharge between discharge cells of each color is also obtained.

Hereinafter, other modifications of the PDP according to the present invention will be described. Modifications described below can be applied in combination with the above Examples 1 to 3 or in combinations of the modifications arbitrarily.

In each said embodiment, the case where the width | variety or length of the transparent electrode 2b, 3b was changed about both the scanning electrode 2 and the sustain electrode 3 was demonstrated. However, only the one of the scan electrode 2 and the sustain electrode 3 may be configured to change the shapes of the transparent electrodes 2b and 3b.

Fig. 7 shows scanning electrodes 2, sustain electrodes 3, and partitions 8 in the case where four adjacent discharge cells of the PDP according to the first modified example of the present invention are viewed from the front panel side in the X direction. It is a schematic diagram shown. As shown in FIG. 7, only by changing the shape of the scan electrode 2, the width / length of the transparent electrode 2b is changed and the gap between the discharge gaps is adjusted in accordance with the first to third embodiments. ought. As for the sustain electrode 3, the widths / lengths of the transparent electrodes 3bR1, 3bG, 3bB, and 3bR2 are all equal.

According to the PDP according to the first modified example of the present invention, in forming the transparent electrodes 2b and 3b, firstly, the transparent electrodes 3b are formed at equal intervals, and then aligned with the transparent electrodes 3b to form the transparent electrodes 2b. Since it is sufficient to form, the scan electrode 2 and the sustain electrode 3 can be manufactured relatively accurately.

In the above embodiments, the transparent electrodes 2b and 3b are formed separately for each discharge cell, and the transparent electrodes 2b and 3b adjacent in the Y direction are electrically connected to each other by the parent electrodes 2a and 3a. It was. However, the transparent electrodes 2b and 3b adjacent in the Y direction may be electrically connected to each other by a part of the transparent electrode.

Fig. 8 is a diagram showing the extraction of the scan electrodes 2, sustain electrodes 3, and partitions 8 in the case of four adjacent discharge cells in the PDP according to Variation 2 of the present invention when viewed along the X direction from the front panel side. It is a schematic diagram shown. The transparent electrode 2bR1 and the transparent electrode 2bG, which are adjacent to each other in the Y direction with respect to the scan electrode 2, are part of the transparent electrode formed on the main surface of the glass substrate 1, not the mother electrode 2a. It is electrically connected with each other by (2a1 in FIG. 8). Moreover, the transparent electrode 3bG and the transparent electrode 3bB which adjoin each other in the Y direction with respect to the sustain electrode 3, for example, are transparent electrodes formed on the main surface of the glass substrate 1, not the mother electrode 3a. Are electrically connected to each other by a part (symbol 3a1 in FIG. 8).

According to the PDP according to the second modification of the present invention, the transparent electrodes 2a1, 2bR1, 2bG, and 2bB are integrally formed of the same material. In addition, the transparent electrodes 3a1, 3bR1, 3bG, and 3bB are integrally formed of the same material. Therefore, when the transparent electrodes 2a1 and the transparent electrodes 2bR1, 2bG, and 2bB are separately formed by different materials, and the transparent electrodes 3a1 and the transparent electrodes 3bR1, 3bG, 3bB are individually formed by different materials. In comparison with the case of forming, the manufacture of the scanning electrode 2 and the sustain electrode 3 can be made easy.

In each of the above embodiments, the scan electrodes 2 and the sustain electrodes 3 are formed by the mother electrodes 2a and 3a and the transparent electrodes 2b and 3b connected to the mother electrodes 2a and 3a, respectively. . However, as described in, for example, Japanese Patent Application Laid-Open No. 8-22772, instead of the transparent electrodes 2b and 3b, frame-shaped electrodes having the same shape as the outer circumference of the transparent electrodes 2b and 3b are modeled. It may be formed using the same material as the electrodes 2a and 3a (that is, a material having a lower conductivity but higher conductivity than that of the transparent electrode).

Fig. 9 shows the scan electrodes 2, sustain electrodes 3, and partitions 8 in the case where four adjacent discharge cells in the PDP according to the third modification of the present invention are seen along the X direction from the front panel side. It is a schematic diagram shown. Frame electrodes 2bb and 3bb made of low-resistance materials such as silver and aluminum on the main surface of the glass substrate 1 (symbols 2bbR1, 2bbG, 2bbB, 2bbR2, 3bbR1, 3bbG, 3bbB and 3bbR2 in Fig. 9). After forming a)), the mother electrodes 2a and 3a are formed on the main surface of the glass substrate 1 by superimposing a part on the frame electrodes 2bb and 3bb.

According to the PDP according to the third modification of the present invention, since the mother electrodes 2a and 3a and the frame electrodes 2bb and 3bb can be formed using the same material, the use of the transparent electrode material becomes unnecessary. The cost can be reduced. In addition, since the electrodes 2bb and 3bb having low light transmittance are formed in a frame shape, the decrease in luminance in the PDP can be suppressed.

In the PDP according to the modification 3, first, the frame electrodes 2bb and 3bb were formed, and then a portion of the mother electrodes 2a and 3a were formed by superimposing a part on the frame electrodes 2bb and 3bb. However, the frame electrodes 2bb and 3bb and the mother electrodes 2a and 3a may be formed by the same process.

Fig. 10 shows the scanning electrodes 2, sustain electrodes 3, and partitions 8 in the case where four adjacent discharge cells in the PDP according to the fourth modified example of the present invention are seen along the X direction from the front panel side. It is a schematic diagram shown. The frame electrodes 2bb and 3bb and the mother electrodes 2a2 and 3a2 are formed in one layer on the main surface of the glass substrate 1 by the same process.

According to the PDP according to the fourth modification of the present invention, in forming the scan electrode 2 and the sustain electrode 3, the mother electrodes 2a and 3a are positioned at predetermined portions on the frame electrodes 2bb and 3bb. The process of forming by forming is unnecessary, and the manufacture can be facilitated. In addition, in the modification 4, as shown in FIG. 11, the mother electrodes 2a2 and 3a2 may be formed only outside the outer circumferential lines of the frame electrodes 2bb and 3bb. By removing the parent electrodes 2a2 and 3a2 of the portion of the frame electrodes 2bb and 3bb in the frame, the area for blocking light from the discharge space toward the glass substrate 1 can be reduced, and the luminance of the PDP can be reduced. Can increase.

Moreover, in each said Example, the fluorescent substance 9 was apply | coated to the surface of the recessed part comprised by the side surface of the partition 8 and the main surface of the glass substrate 6 in the back panel. However, the phosphor may also be formed on the front panel side.

Fig. 12 shows the scan electrodes 2, sustain electrodes 3, and partitions 8 in the case where four adjacent discharge cells in the PDP according to the modification 5 of the present invention are viewed along the X direction from the front panel side. It is a schematic diagram shown. In Fig. 12, phosphors of the same color as the phosphors applied on the rear panel side are bound to a portion not overlapping the planar sagittal electrodes 2b and 3b and the partition wall 8 subjected to diagonal hatching. Inorganic solvents including ultrafine particles of silica) are mixed and formed on the protective film 5 to a predetermined thickness. However, as long as the phosphors formed in the adjacent cells do not interfere with each other, the phosphors may be formed at portions overlapping the planar sagittal partition 8.

In addition, the protective film 5 is not formed on the entire surface of the dielectric layer 4, but is formed only in a portion overlapping with the planar sagittal scan electrode 2 and the sustain electrode 3, and the scan electrode 2 and the sustain electrode 3 are formed. On the dielectric layer 4 of the portion exposed from the cross-section), the phosphors may be formed so that the phosphors formed in adjacent cells do not interfere with each other. In this case, it is not necessary to mix the said binder.

The phosphor may be formed between the dielectric layer 4 and the protective film 5 instead of being formed on the protective film 5. Also in this case, it is preferable to form the phosphor only in the portion overlapping with the planar sagittal scan electrode 2 and the sustain electrode 3.

According to the PDP according to the fifth modification of the present invention, since the phosphor 9 is applied not only to the rear panel side but also to a predetermined portion on the front panel side, the luminance of the PDP can be increased.

In addition, the description of the modification 5 described the case where the invention according to the modification 5 was applied to the PDP of the type in which the transparent electrodes 2b and 3b were formed. However, the invention according to the modification 5 described above can also be applied to the PDP of the type in which the frame electrodes 2bb and 3bb are formed.

Fig. 13 shows the scanning electrodes 2, the sustain electrodes 3 and the partition walls 8 in the case where four adjacent discharge cells in the PDP according to the modification 6 of the present invention are seen along the X direction from the front panel side. It is a schematic diagram shown. In FIG. 13, phosphors of the same color as the phosphors applied on the rear panel side are formed in a predetermined thickness at portions not overlapping with the planar sagittal frame electrodes 2bb and 3bb and the partition wall 8 subjected to diagonal hatching. It is applied on the protective film 5.

In the above embodiments, the mother electrodes 2a and 3a are arranged on the ends of the transparent electrodes 2b and 3b on the opposite side to the discharge gap, but the mother electrodes 2a and 3b are supplied to supply current to the transparent electrodes 2b and 3b. In order to exert the functions of the electrodes 2a and 3a, the mother electrodes 2a and 3a do not necessarily need to be disposed on the ends of the transparent electrodes 2b and 3b, for example, in the center of the transparent electrodes 2b and 3b. It may be placed on a wound.

Moreover, since this invention relates to the structure of the front panel of a PDP, not only the back panel shown in FIG. 1 but a back panel of arbitrary structures can be employ | adopted as a back panel. For example, the distance between adjacent partitions as described in Japanese Patent Application Laid-open No. Hei 10-308179 referred to in the description of the prior art may adopt a different type of rear panel for each discharge cell of each color.

In addition, a plasma display device having excellent display characteristics can be obtained by combining the PDP according to the present invention with a known drive circuit for driving the PDP.

According to the plasma display panel according to the first aspect of the present invention, by varying the area of the branch of the first electrode, the amount of ultraviolet irradiation to the phosphor can be varied for each color. Therefore, the larger the unit discharge region in the case where the same amount of ultraviolet rays are irradiated, the larger the area of the branch portion of the first electrode can be made to match the emission intensity between the unit discharge regions of each color.

Further, according to the plasma display panel according to the second aspect of the present invention, the area of the branch portion of the first electrode can be changed for each color of light by varying the width of the branch portion in the first direction.

In addition, according to the plasma display panel according to the third aspect of the present invention, by varying the length of the branch portion in the second direction, the area of the branch portion of the first electrode can be changed for each color of emission. In addition, the tolerance of misalignment when joining the first substrate and the second substrate can be sufficiently secured for each of the emission colors.

In addition, according to the plasma display panel according to the fourth aspect of the present invention, it is possible to minimize the decrease in the emission luminance of the plasma display panel due to the presence of the trunk portion of the first electrode.

In addition, according to the plasma display panel according to the fifth aspect of the present invention, the occurrence probability of sustain discharge can be varied for each color by varying the interval in the second direction of the discharge gap. Therefore, by setting the unit discharge region having a higher write discharge start voltage so that the interval in the second direction of the discharge gap is narrower, the probability of occurrence of sustain discharge can be made uniform among the unit discharge regions of each light emission color.

In addition, according to the plasma display panel according to the sixth aspect of the present invention, after forming the first or second electrodes having different areas of the branch portions, they are positioned to the electrodes, and the second or second portions having different areas of the branch portions are formed. One electrode can be formed. Therefore, the first and second electrodes can be manufactured with relatively high accuracy.

Further, according to the plasma display panel according to the seventh aspect of the present invention, the manufacturing of the first electrode can be facilitated as compared with the case where the trunk portion and the branch portion of the first electrode are formed separately from different materials. have.

In addition, according to the plasma display panel according to the eighth aspect of the present invention, even if the material of the branch portion of the first electrode is a material having low light transmittance, it is possible to suppress a decrease in luminance in the plasma display panel.

In addition, according to the plasma display panel according to the ninth aspect of the present invention, it is not necessary to position and form the trunk portion of the first electrode in a predetermined portion on the branch portion of the first electrode, thereby facilitating manufacturing. have.

In addition, according to the plasma display panel according to the tenth aspect of the present invention, by not forming the trunk portion of the portion formed inside the outer circumferential line of the branch portion of the first electrode, the luminance decrease in the plasma display panel is further suppressed. can do.

Further, according to the plasma display panel according to the eleventh aspect of the present invention, the probability of occurrence of sustain discharge can be varied for each color by varying the interval in the second direction of the discharge gap. Therefore, by setting the unit discharge region having a higher write discharge start voltage so that the interval in the second direction of the discharge gap is narrower, the probability of occurrence of sustain discharge can be matched between the unit discharge regions of each light emission color.

In addition, according to the plasma display panel according to the twelfth aspect of the present invention, since the phosphor is formed not only on the second substrate side but also on the first substrate side which is the display surface, the luminance of the plasma display panel can be increased.

Further, according to the plasma display device according to the thirteenth aspect of the present invention, a plasma display device excellent in display characteristics can be obtained.

Claims (3)

A first substrate which is a display surface, A second substrate facing the first substrate with a discharge space in which a plurality of unit discharge regions are arranged in a matrix shape; A first electrode and a second electrode formed on a main surface of the first substrate on the discharge space side and forming a pair provided for each row of the plurality of unit discharge regions; A third electrode formed on the main surface of the second substrate on the discharge space side and provided for each column of the plurality of unit discharge regions; At least two or more phosphors formed on the main surface of the second substrate by covering the third electrode, and having different emission colors; The first electrode, A trunk portion extending along the first direction, which is the row direction, A branch portion connected to the trunk portion and provided in each of the unit discharge regions and protruding in the second direction in the column direction; The second electrode, A trunk portion extending along the first direction, A branch part connected to the trunk part and provided in each of the unit discharge regions, protruding in the second direction and defining a discharge gap between the branch parts of the first electrode, And an area of the branch portion of at least one of the first electrode and the second electrode is different between the plurality of unit discharge regions for each of emission colors. A first substrate which is a display surface, A second substrate facing the first substrate with a discharge space in which a plurality of unit discharge regions are arranged in a matrix shape; A first electrode and a second electrode formed on a main surface of the first substrate on the discharge space side and forming a pair provided for each row of the plurality of unit discharge regions; A third electrode formed on the main surface of the second substrate on the discharge space side and provided for each column of the plurality of unit discharge regions; At least two or more phosphors formed on the main surface of the second substrate by covering the third electrode, and having different emission colors; The first electrode, A trunk portion extending along the first direction, the row direction; It is connected to the trunk portion is provided for each unit discharge region, and has a branch portion protruding in the second direction of the column direction, The second electrode, A trunk portion extending along the first direction, A branch part connected to the trunk part and provided in each unit discharge region, protruding in the second direction to define a discharge gap between the branch part of the first electrode, And the intervals in the second direction of the discharge gap are different between the plurality of unit discharge regions for each of emission colors. The plasma display panel according to claim 1 or 2, A driving circuit for driving the plasma display panel Plasma display device having a.